# Copyright (c) 2012 The Chromium Authors. All rights reserved. # Use of this source code is governed by a BSD-style license that can be # found in the LICENSE file. import os from code import Code from model import PropertyType import cpp_util import schema_util class HGenerator(object): def __init__(self, type_generator): self._type_generator = type_generator def Generate(self, namespace): return _Generator(namespace, self._type_generator).Generate() class _Generator(object): """A .h generator for a namespace. """ def __init__(self, namespace, cpp_type_generator): self._namespace = namespace self._type_helper = cpp_type_generator self._generate_error_messages = namespace.compiler_options.get( 'generate_error_messages', False) def Generate(self): """Generates a Code object with the .h for a single namespace. """ c = Code() (c.Append(cpp_util.CHROMIUM_LICENSE) .Append() .Append(cpp_util.GENERATED_FILE_MESSAGE % self._namespace.source_file) .Append() ) # Hack: for the purpose of gyp the header file will always be the source # file with its file extension replaced by '.h'. Assume so. output_file = os.path.splitext(self._namespace.source_file)[0] + '.h' ifndef_name = cpp_util.GenerateIfndefName(output_file) # Hack: tabs and windows have circular references, so only generate hard # references for them (i.e. anything that can't be forward declared). In # other cases, generate soft dependencies so that they can include # non-optional types from other namespaces. include_soft = self._namespace.name not in ('tabs', 'windows') (c.Append('#ifndef %s' % ifndef_name) .Append('#define %s' % ifndef_name) .Append() .Append('#include ') .Append() .Append('#include ') .Append('#include ') .Append('#include ') .Append() .Append('#include "base/logging.h"') .Append('#include "base/memory/linked_ptr.h"') .Append('#include "base/memory/scoped_ptr.h"') .Append('#include "base/values.h"') .Cblock(self._type_helper.GenerateIncludes(include_soft=include_soft)) .Append() ) # Hack: we're not generating soft includes for tabs and windows, so we need # to generate forward declarations for them. if not include_soft: c.Cblock(self._type_helper.GenerateForwardDeclarations()) cpp_namespace = cpp_util.GetCppNamespace( self._namespace.environment.namespace_pattern, self._namespace.unix_name) c.Concat(cpp_util.OpenNamespace(cpp_namespace)) c.Append() if self._namespace.properties: (c.Append('//') .Append('// Properties') .Append('//') .Append() ) for prop in self._namespace.properties.values(): property_code = self._type_helper.GeneratePropertyValues( prop, 'extern const %(type)s %(name)s;') if property_code: c.Cblock(property_code) if self._namespace.types: (c.Append('//') .Append('// Types') .Append('//') .Append() .Cblock(self._GenerateTypes(self._FieldDependencyOrder(), is_toplevel=True, generate_typedefs=True)) ) if self._namespace.functions: (c.Append('//') .Append('// Functions') .Append('//') .Append() ) for function in self._namespace.functions.values(): c.Cblock(self._GenerateFunction(function)) if self._namespace.events: (c.Append('//') .Append('// Events') .Append('//') .Append() ) for event in self._namespace.events.values(): c.Cblock(self._GenerateEvent(event)) (c.Concat(cpp_util.CloseNamespace(cpp_namespace)) .Append('#endif // %s' % ifndef_name) .Append() ) return c def _FieldDependencyOrder(self): """Generates the list of types in the current namespace in an order in which depended-upon types appear before types which depend on them. """ dependency_order = [] def ExpandType(path, type_): if type_ in path: raise ValueError("Illegal circular dependency via cycle " + ", ".join(map(lambda x: x.name, path + [type_]))) for prop in type_.properties.values(): if (prop.type_ == PropertyType.REF and schema_util.GetNamespace(prop.ref_type) == self._namespace.name): ExpandType(path + [type_], self._namespace.types[prop.ref_type]) if not type_ in dependency_order: dependency_order.append(type_) for type_ in self._namespace.types.values(): ExpandType([], type_) return dependency_order def _GenerateEnumDeclaration(self, enum_name, type_): """Generate a code object with the declaration of a C++ enum. """ c = Code() c.Sblock('enum %s {' % enum_name) c.Append(self._type_helper.GetEnumNoneValue(type_) + ',') for value in type_.enum_values: current_enum_string = self._type_helper.GetEnumValue(type_, value) c.Append(current_enum_string + ',') c.Append('%s = %s,' % ( self._type_helper.GetEnumLastValue(type_), current_enum_string)) c.Eblock('};') return c def _GenerateFields(self, props): """Generates the field declarations when declaring a type. """ c = Code() needs_blank_line = False for prop in props: if needs_blank_line: c.Append() needs_blank_line = True if prop.description: c.Comment(prop.description) # ANY is a base::Value which is abstract and cannot be a direct member, so # we always need to wrap it in a scoped_ptr. is_ptr = prop.optional or prop.type_.property_type == PropertyType.ANY (c.Append('%s %s;' % ( self._type_helper.GetCppType(prop.type_, is_ptr=is_ptr), prop.unix_name)) ) return c def _GenerateType(self, type_, is_toplevel=False, generate_typedefs=False): """Generates a struct for |type_|. |is_toplevel| implies that the type was declared in the "types" field of an API schema. This determines the correct function modifier(s). |generate_typedefs| controls whether primitive types should be generated as a typedef. This may not always be desired. If false, primitive types are ignored. """ classname = cpp_util.Classname(schema_util.StripNamespace(type_.name)) c = Code() if type_.functions: # Wrap functions within types in the type's namespace. (c.Append('namespace %s {' % classname) .Append() ) for function in type_.functions.values(): c.Cblock(self._GenerateFunction(function)) c.Append('} // namespace %s' % classname) elif type_.property_type == PropertyType.ARRAY: if generate_typedefs and type_.description: c.Comment(type_.description) c.Cblock(self._GenerateType(type_.item_type, is_toplevel=is_toplevel)) if generate_typedefs: (c.Append('typedef std::vector<%s > %s;' % ( self._type_helper.GetCppType(type_.item_type), classname)) ) elif type_.property_type == PropertyType.STRING: if generate_typedefs: if type_.description: c.Comment(type_.description) c.Append('typedef std::string %(classname)s;') elif type_.property_type == PropertyType.ENUM: if type_.description: c.Comment(type_.description) c.Cblock(self._GenerateEnumDeclaration(classname, type_)); # Top level enums are in a namespace scope so the methods shouldn't be # static. On the other hand, those declared inline (e.g. in an object) do. maybe_static = '' if is_toplevel else 'static ' (c.Append() .Append('%sstd::string ToString(%s as_enum);' % (maybe_static, classname)) .Append('%s%s Parse%s(const std::string& as_string);' % (maybe_static, classname, classname)) ) elif type_.property_type in (PropertyType.CHOICES, PropertyType.OBJECT): if type_.description: c.Comment(type_.description) (c.Sblock('struct %(classname)s {') .Append('%(classname)s();') .Append('~%(classname)s();') ) if 'use_movable_types' in type_.namespace.compiler_options: (c.Append('%(classname)s(%(classname)s&& rhs);') .Append('%(classname)s& operator=(%(classname)s&& rhs);') ) if type_.origin.from_json: (c.Append() .Comment('Populates a %s object from a base::Value. Returns' ' whether |out| was successfully populated.' % classname) .Append('static bool Populate(%s);' % self._GenerateParams( ('const base::Value& value', '%s* out' % classname))) ) if is_toplevel: (c.Append() .Comment('Creates a %s object from a base::Value, or NULL on ' 'failure.' % classname) .Append('static scoped_ptr<%s> FromValue(%s);' % ( classname, self._GenerateParams(('const base::Value& value',)))) ) if type_.origin.from_client: value_type = ('base::Value' if type_.property_type is PropertyType.CHOICES else 'base::DictionaryValue') (c.Append() .Comment('Returns a new %s representing the serialized form of this ' '%s object.' % (value_type, classname)) .Append('scoped_ptr<%s> ToValue() const;' % value_type) ) if type_.property_type == PropertyType.CHOICES: # Choices are modelled with optional fields for each choice. Exactly one # field of the choice is guaranteed to be set by the compiler. c.Cblock(self._GenerateTypes(type_.choices)) c.Append('// Choices:') for choice_type in type_.choices: c.Append('%s as_%s;' % ( self._type_helper.GetCppType(choice_type, is_ptr=True), choice_type.unix_name)) else: properties = type_.properties.values() (c.Append() .Cblock(self._GenerateTypes(p.type_ for p in properties)) .Cblock(self._GenerateFields(properties))) if type_.additional_properties is not None: # Most additionalProperties actually have type "any", which is better # modelled as a DictionaryValue rather than a map of string -> Value. if type_.additional_properties.property_type == PropertyType.ANY: c.Append('base::DictionaryValue additional_properties;') else: (c.Cblock(self._GenerateType(type_.additional_properties)) .Append('std::map additional_properties;' % cpp_util.PadForGenerics( self._type_helper.GetCppType(type_.additional_properties, is_in_container=True))) ) (c.Eblock() .Append() .Sblock(' private:') .Append('DISALLOW_COPY_AND_ASSIGN(%(classname)s);') .Eblock('};') ) return c.Substitute({'classname': classname}) def _GenerateEvent(self, event): """Generates the namespaces for an event. """ c = Code() # TODO(kalman): use event.unix_name not Classname. event_namespace = cpp_util.Classname(event.name) (c.Append('namespace %s {' % event_namespace) .Append() .Concat(self._GenerateEventNameConstant(event)) .Concat(self._GenerateCreateCallbackArguments(event)) .Append('} // namespace %s' % event_namespace) ) return c def _GenerateFunction(self, function): """Generates the namespaces and structs for a function. """ c = Code() # TODO(kalman): Use function.unix_name not Classname here. function_namespace = cpp_util.Classname(function.name) # Windows has a #define for SendMessage, so to avoid any issues, we need # to not use the name. if function_namespace == 'SendMessage': function_namespace = 'PassMessage' (c.Append('namespace %s {' % function_namespace) .Append() .Cblock(self._GenerateFunctionParams(function)) ) if function.callback: c.Cblock(self._GenerateFunctionResults(function.callback)) c.Append('} // namespace %s' % function_namespace) return c def _GenerateFunctionParams(self, function): """Generates the struct for passing parameters from JSON to a function. """ if not function.params: return Code() c = Code() (c.Sblock('struct Params {') .Append('static scoped_ptr Create(%s);' % self._GenerateParams( ('const base::ListValue& args',))) .Append('~Params();') .Append() .Cblock(self._GenerateTypes(p.type_ for p in function.params)) .Cblock(self._GenerateFields(function.params)) .Eblock() .Append() .Sblock(' private:') .Append('Params();') .Append() .Append('DISALLOW_COPY_AND_ASSIGN(Params);') .Eblock('};') ) return c def _GenerateTypes(self, types, is_toplevel=False, generate_typedefs=False): """Generate the structures required by a property such as OBJECT classes and enums. """ c = Code() for type_ in types: c.Cblock(self._GenerateType(type_, is_toplevel=is_toplevel, generate_typedefs=generate_typedefs)) return c def _GenerateCreateCallbackArguments(self, function): """Generates functions for passing parameters to a callback. """ c = Code() params = function.params c.Cblock(self._GenerateTypes((p.type_ for p in params), is_toplevel=True)) declaration_list = [] for param in params: if param.description: c.Comment(param.description) declaration_list.append(cpp_util.GetParameterDeclaration( param, self._type_helper.GetCppType(param.type_))) c.Append('scoped_ptr Create(%s);' % ', '.join(declaration_list)) return c def _GenerateEventNameConstant(self, event): """Generates a constant string array for the event name. """ c = Code() c.Append('extern const char kEventName[]; // "%s.%s"' % ( self._namespace.name, event.name)) c.Append() return c def _GenerateFunctionResults(self, callback): """Generates namespace for passing a function's result back. """ c = Code() (c.Append('namespace Results {') .Append() .Concat(self._GenerateCreateCallbackArguments(callback)) .Append('} // namespace Results') ) return c def _GenerateParams(self, params): """Builds the parameter list for a function, given an array of parameters. """ # |error| is populated with warnings and/or errors found during parsing. # |error| being set does not necessarily imply failure and may be # recoverable. # For example, optional properties may have failed to parse, but the # parser was able to continue. if self._generate_error_messages: params += ('base::string16* error',) return ', '.join(str(p) for p in params)